Global ETD Search

111	Caractérisation des progéniteurs cellulaires exprimant les aldéhydes déshydrogénases (ALDH) dans des modèles sains et dystrophiques / Characterization of progenitor cells expressing aldehyde dehydrogenase (ALDH) in healthy and dystrophic models Etienne, Jessy 21 December 2016 (has links) La thérapie cellulaire est une envisagée pour traiter des pathologies cardiaques ou squelettiques basée sur la médecine régénérative. Les progéniteurs cellulaires classiquement utilisés (myoblastes ou cellules mésenchymateuses) n'ont démontré qu'une efficacité limitée. Dans ce contexte, notre laboratoire a identifié une nouvelle catégorie de progéniteurs, sur la base de leur activité enzymatique aldéhyde déshydrogénase (ALDH) mise en évidence par un substrat fluorescent, l'Aldéfluor, et en association avec le marqueur CD34. Les ALDH sont impliquées dans le métabolisme et la détoxification des aldéhydes, et constituent un nouveau marqueur des cellules souches. Ce travail de thèse a permis de mieux caractériser les progéniteurs myogéniques (ALDH+/CD34-) et non myogéniques (ALDH+/CD34+), dans différents contextes physiopathologiques. Leur présence dans différents muscles de primates humains ou non humains, leur persistance au cours du vieillissement naturel ou lors d'atteinte par la dystrophie musculaire de Duchenne (DMD) chez l'Homme et dans des modèles animaux, suggèrent une utilisation possible des cellules ALDH+/CD34- pour des développements thérapeutiques ultérieurs. L'étude phénotypique révèle que des marqueurs transmembranaires sont associés à des sous-populations de cellules ALDH myogéniques ou non myogéniques dont la comparaison permettra de proposer de meilleurs candidats de thérapie cellulaire. En parallèle, les caractérisations histologiques et cytologiques ont identifié des sous-populations exprimant des isoenzymes et les analyses d'expressiongénique réalisées ex vivo et en culture suggèrent que certaines sont impliquées dans l'homéostasie musculaires. / Cell therapy is a regenerative medicine strategy considered for the treatment of cardiac or skeletal muscle diseases. The cellular progenitors used to date (myoblasts or mesenchymal stem cells) provided mitigated success, thus mandating the identification and characterization of new categories of progenitors. Our laboratory has identified new populations of progenitors, based on their Aldehyde Deshydrogenase activity (ALDH) detectable using the fluorescent substrate Aldefluor, associated with the expression of the CD34 marker. ALDH are involved in metabolism and detoxification of aldehydes, they play important roles in cell survival and differentiation and are considered a new marker of stem cells. The present project allowed characterizing extensively the myogenic (ALDH+/CD34-) and non myogenic (ALDH+/CD34+) progenitors, in several physiopathological contexts and animal models. The presence of ALDH+/CD34- cells in distinct muscle groups in Human and non-human Primates, their persistence through natural ageing and despite the ongoing degenerative process observed in Duchenne muscular dystrophy in Human patients and animal models suggest their future use for therapeutic applications. The phenotypic characterization indicated that membrane markers are associated to myogenic or non myogenic sub-populations of ALDH cells. The comparison on their efficacies in vito and in vivo will allow proposing new candidates for cell therapy. In parallele, histological and cytological analysis identified cell populations expressing isoenzymes The analysis of gene expressions suggested that, at least, some of them are involved in muscle homeostasis in situ or in vitro. Aldéhydes déshydrogénases (ALDH) Dystrophie musculaire de Duchenne (DMD) Progéniteurs myogéniques Thérapie cellulaire Cell therapy Aldehyde Deshydrogenase Duchenne muscular dystrophy Myogenic progenitors 572.8
112	Characterization of the Protein Lysine Methyltransferase SMYD2 Lanouette, Sylvain January 2015 (has links) Our understanding of protein lysine methyltransferases and their substrates remains limited despite their importance as regulators of the proteome. The SMYD (SET and MYND domain) methyltransferase family plays pivotal roles in various cellular processes, including transcriptional regulation and embryonic development. Among them, SMYD2 is associated with oesophageal squamous cell carcinoma, bladder cancer and leukemia as well as with embryonic development. Initially identified as a histone methyltransferase, SMYD2 was later reported to methylate p53, the retinoblastoma protein pRb and the estrogen receptor ERalpha and to regulate their activity. Our proteomic and biochemical analyses demonstrated that SMYD2 also methylates the molecular chaperone HSP90 on K209 and K615. We also showed that HSP90 methylation is regulated by HSP90 co-chaperones, pH, and the demethylase LSD1. Further methyltransferase assays demonstrated that SMYD2 methylates lysine K* in proteins which include the sequence [LFM]-₁-K*-[AFYMSHRK]+₁-[LYK]+₂. This motif allowed us to show that SMYD2 methylates the transcriptional co-repressor SIN3B, the RNA helicase DHX15 and the myogenic transcription factors SIX1 and SIX2. Finally, muscle cell models suggest that SMYD2 methyltransferase activity plays a role in preventing premature myogenic differentiation of proliferating myoblasts by repressing muscle-specific genes. Our work thus shows that SMYD2 methyltransferase activity targets a broad array of substrates in vitro and in situ and is regulated by intricate mechanisms. Lysine Methylation Post-Translational Modifications SMYD2 SET Methyltransferase SMYD HSP90 Myogenic Differentiation Computational Protein Design Multi-State Design SIX1 SIX2 DHX15 SIN3
113	Identificação e caracterização de seqüências expressas (EST) na musculatura peitoral de frangos de corte. / Identification and characterization of expressed sequence tags (EST) in broilers breast muscle. Helena Javiel Alves 23 November 2004 (has links) A produção de aves no Brasil vem crescendo na ordem de 10% a cada ano, o que se explica pela atualização constante da tecnologia do setor (http://www.abef.com.br). Sendo a carne de frango a fonte de proteína animal mais barata e acessível ao consumidor, há necessidade de se produzir cada vez mais animais com maior acúmulo de massa muscular. Para isso, o entendimento dos mecanismos celulares e moleculares envolvidos na formação da musculatura esquelética é de extrema relevância. Os fatores miogênicos, genes responsáveis pela determinação e diferenciação de células musculares, foram clonados e progressos significativos foram desenvolvidos quanto ao controle da expressão dos mesmos. A utilização da técnica de seqüenciamento de DNA possibilita a identificação e caracterização de novos genes envolvidos na complexa rede de fatores que regulam a formação da musculatura esquelética em aves. Neste estudo, foram construídas duas bibliotecas de cDNA (fase embrionária e pós-eclosão) de músculo peitoral de uma linhagem de corte (TT) e uma biblioteca da fase embrionária de uma linhagem de postura (CC). A análise das seqüências EST (Expressed Sequence Tags) foi utilizada para identificar possíveis novos genes envolvidos no processo de formação da musculatura esquelética. As seqüências EST identificadas possibilitaram a construção de um banco com 6247 ESTs da musculatura peitoral das linhagens de corte e postura nas duas fases de desenvolvimento. Com o intuito de estabelecer uma relação entre o perfil de expressão dos fatores miogênicos: MyoD, MRF4 e miogenina; e dos genes Pax-3 e miostatina e a formação e maturação das fibras musculares, foi utilizada a técnica de PCR em tempo real. Em geral, a expressão dos fatores miogênicos foi maior na linhagem de corte em relação à de postura nas idades estudadas. Este estudo deverá contribuir para as áreas celular e molecular de desenvolvimento, além de fornecer recursos úteis aos programas de melhoramento genético de aves que visam obter animais com maior acúmulo de massa muscular. / Brazilians chicken production is increasing annually around 10%, which can be explained by the current technology applied to this sector (http://www.abef.com.br). Being chickens meat the cheapest animal protein source for consumers, there is a need to produce even more animals with increased muscular mass. For this purpose, understanding the molecular and cellular mechanisms involved with the skeletal muscle development is of great relevance. The myogenic factors, genes responsible for the determination and differentiation of muscle cells, were cloned and significant progress was made on the control of their expression. The use of DNA sequencing technique allows the identification and characterization of new genes involved in the complex chain of factors signalling systems that regulates the expression of avian skeletal muscles. In this study, two cDNA libraries (embryonic and post-hatching phases) were constructed from the breast muscle of a chicken broiler line (TT) and one library, from the embryonic phase, from a chicken layer line (CC). The EST (Expressed Sequencing Tags) analysis was used to identify probable new genes involved in the skeletal muscle development. The identified ESTs were used to generate a database containing 6247 breast muscle ESTs from two chicken lines in two development phases. Real time PCR was employed with the aim of establishing a relationship among the expression profile of myogenic factors (MyoD, MFR4, and myogenin), Pax-3 and myostatin genes with the formation and maturation of muscle fibers. In general, the expression of myogenic factors was greater in the broiler than in the layer chicken line in the phases under study. These results should contribute to other cellular and molecular development studies besides providing useful resources for chicken breeding programs whose objective is the deposition of skeletal muscle mass. biologia animal desenvolvimento animal expressão gênica frangos de corte linhagem animal melhoramento genético animal breast muscle chicken expression sequence tags (ESTs) gene expression myogenic factors myostatin
114	Les progéniteurs fibro-adipogéniques des muscles squelettiques humains sains et dystrophiques : caractérisation et interactions avec les progéniteurs myogéniques et les macrophages / Fibro-adipogenic progenitors in healthy and dystrophic human skeletal muscles : characterization and interactions with myogenic progenitors and macrophages Moratal, Claudine 13 December 2016 (has links) La régénération musculaire implique des interactions fonctionnelles entre différents types de cellules mononucléées. Parmi elles, citons les progéniteurs myogéniques (MPs), qui fusionnent pour générer de nouvelles myofibres en réponse à une blessure, et les cellules immunitaires qui envahissent les muscles endommagés. Des dépôts transitoires fibrotiques et d’adipocytes sont observés dans les muscles en régénération qui cependant persistent dans la dystrophie musculaire de Duchenne (DMD) et au cours du vieillissement. Nous avons démontré que les progéniteurs fibro-adipogéniques (FAPs) exprimant le marqueur de surface PDGFRα, contribueraient au développement des dépôts non myogéniques dans les muscles sains. En effet, ces progéniteurs se différencient en adipocytes blancs fonctionnels, bien qu’étant insensibles à l’insuline, et génèrent des myofibroblastes. Quant à la fibrose des muscles DMD, elle se formerait à partir de la différenciation à la fois des MPs et des FAPs. Dans les muscles sains, les FAPs stimulent la myogenèse des MPs au cours de la régénération, alors que les myotubes et les macrophages pro-inflammatoires inhibent l’adipogenèse et la fibrogenèse des FAPs. Pour les progéniteurs âgés ou dystrophiques, les interactions cellulaires entre les FAPs et les MPs sont perturbées. De manière intéressante, la régulation des FAPs DMD ou âgés peut être restaurée en remplaçant les MPs DMD ou âgés par des MPs jeunes et sains. Nos résultats montrent que les muscles humains contiennent des progéniteurs fibro-adipogéniques qui jouent un rôle central dans la régulation de l’homéostasie musculaire en interagissant avec les progéniteurs myogéniques et les macrophages / Muscle regeneration involves functional interactions between different types of mononuclear cells including myogenic progenitors (MPs) and macrophages. Following injury, damaged muscles are invaded by immune cells and MPs fuse to generate new myofibres. Transient fibrotic and adipocyte deposits are observed in regenerating muscles, which however persist in Duchenne muscular dystrophy (DMD) and during aging. We demonstrated that fibro-adipogenic progenitors (FAPs) expressing the PDGFRα surface marker would contribute to the development of non-myogenic deposits in healthy muscles. Indeed, these progenitors differentiate into functional white adipocytes that have the feature to be insulino-resistant, and give rise to myofibroblastes. Intramuscular fibrosis in DMD patients could be formed from both FAPs and MPs differentiation. In healthy muscles, FAPs stimulate myogenesis of MPs during regeneration, while myotubes and pro-inflammatory macrophages inhibit the adipogenesis and fibrogenesis of FAPs. Cellular interactions between FAPs and MPs are disrupted for DMD or aged progenitors. Interestingly, they are restored if aged or DMD FAPs are replaced by healthy and young MPs. Our results show that the human muscles contain fibro-adipogenic progenitors that play a crucial role in the control of muscle homeostasis by interacting with myogenic progenitors and macrophages Régénération musculaire Progéniteur fibro-adipogénique Progéniteur myogénique Fibrogenèse Myogénèse Dystrophie musculaire de Duchenne Muscular regeneration Fibro-adipogenic progenitor Myogenic progenitor Adipogenesis Fibrogenesis Duchenne muscular dystrophy
115	The Effects of Simultaneous Thermal and Nutrient Challenge on Broiler Muscle Growth, Meat Quality, and Underlying Cellular Mechanisms Braden, Jennifer Marie January 2019 (has links) No description available. Agriculture Animal Sciences
116	Elucidating the Molecular and Cellular Mechanism Underlying Cancer Cachexia He, Wei January 2013 (has links) No description available. Biology Cellular Biology Molecular Biology Genetics Cancer cachexia Pax7 NF-kB muscle regeneration microvesicles miRNA apoptosis myogenic program cachexia C-26
117	The Effect of Age and Nutrient Status on Growth Characteristics of Turkey Satellite Cells Harthan, Laura Beth 17 December 2013 (has links) No description available. Animal Sciences Agriculture Aging Cellular Biology Nutrition satellite cell turkey muscle age effects nutrition myogenic regulatory factors syndecan-4 glypican-1 adult myoblast
118	The Role of Chicken Delta-Like Protein 1 Expression in Skeletal Muscle Development and Regeneration Shin, Jonghyun 01 October 2009 (has links) No description available. Biology Chicken Delta-Like Protein 1 (gDLK1) Myogenic Regulatory Factors (MRFs) Muscle hypertrophy Development Regeneration Cell Differentiation Myofibers Broilers Leghorn Layers Low Score Normal (LSN) Muscular Dystrophy (MD)
119	Étude de l’impact de la pression pulsée sur la réactivité cérébrovasculaire Raignault, Adeline 08 1900 (has links) In vivo, la pression artérielle au niveau des artères cérébrales est pulsée, alors que ex vivo, l’étude de la fonction cérébrovasculaire est majoritairement mesurée en pression statique. L’impact de la pression pulsée sur la régulation du tonus myogénique et sur la fonction endothéliale cérébrale est inconnu. Nous avons posé l’hypothèse selon laquelle en présence d'une pression pulsée physiologique, la dilatation dépendante de l’endothélium induite par le flux et le tonus myogénique seraient optimisés. L’objectif de notre étude est d’étudier ex vivo l’impact de la pression pulsée sur le tonus myogénique et la dilatation induite par le flux dans les artères cérébrales de souris. Nous avons utilisé un artériographe pressurisé couplé à un système générant une onde pulsée de fréquence et d’amplitude réglables. Les artères cérébrales moyennes (≈160 μm de diamètre) ont été isolées de souris C57BL6 âgées de 3 mois et pressurisées à 60 mm Hg, en pression statique ou en pression pulsée. En pression statique, le tonus myogénique est faible mais est potentialisé par le L-NNA (un inhibiteur de la eNOS) et la PEG-catalase (qui dégrade le H2O2), suggérant une influence des produits dilatateurs dérivés de la eNOS sur le tonus myogénique. En présence de pression pulsée (pulse de 30 mm Hg, pression moyenne de 60 mm Hg, 550 bpm), le tonus myogénique est significativement augmenté, indépendamment du L-NNA et de la PEG-catalase, suggérant que la pression pulsée lève l’impact de la eNOS. En pression statique ou pulsée, les artères pré-contractées se dilatent de façon similaire jusqu’à une force de cisaillement de 15 dyn/cm2. Cette dilatation, dépendante de l’endothélium et de la eNOS, est augmentée en condition pulsée à une force de cisaillement de 20 dyn/cm2. En présence de PEG-catalase, la dilatation induite par le flux est diminuée en pression statique mais pas en pression pulsée, suggérant que la pression statique, mais pas la pression pulsée, favorise la production de O2 -/H2O2. En effet, la dilatation induite par le flux est associée à une production de O2 -/H2O2 par la eNOS, mesurable en pression statique, alors que la dilatation induite par le flux en pression pulsée est associée à la production de NO. Les différences de sensibilité à la dilatation induite par le flux ont été abolies après inhibition de Nox2, en condition statique ou pulsée. La pression pulsée physiologique régule donc l’activité de la eNOS cérébrale, en augmentant le tonus myogénique et, en présence de flux, permet la relâche de NO via la eNOS. / While in vivo arterial blood pressure in cerebral arteries is pulsatile, in vitro cerebral arterial function is generally assessed under a static pressure. Thus, whether pulse pressure regulates cerebral endothelial shear stress sensitivity and myogenic tone is unknown. We hypothesized that a physiological pulse pressure induces a better flow-mediated dilation and optimized myogenic tone. The aim of this study was to test in vitro the impact of pulse pressure on myogenic tone and eNOS-dependent flow-mediated dilation in mouse cerebral arteries. Using a custom computer-controlled pneumatic system generating a pulse pressure (used at 30 mm Hg, rate of 550 bpm) coupled to an arteriograph, isolated posterior cerebral arteries from 3-month old C57Bl/6J mice were pressurized at 60 mm Hg, either in static or pulse pressure conditions. Shear stress from 2 to 20 dyn/cm2 was applied and flow-mediated dilation measured. Without pulse pressure, myogenic tone was low but potentiated by both L-NNA (eNOS inhibitor) and PEG-catalase (catalyses H2O2), suggesting an influence of eNOS-derived dilator products on myogenic tone. Pulse pressure significantly increased myogenic tone, independently of L-NNA and PEG-catalase, suggesting that pulse pressure prevents the impact of eNOS. In both static and pulse pressure conditions, cerebral arteries did not dilate to shear stress in the presence of L-NNA or after endothelial denudation, confirming the endothelial origin of the dilatory response. Up to 15 dyn/cm2, shear stress elicited similar flow-mediated dilation in static and pulse pressure conditions; at 20 dyn/cm2, however, flow-mediated dilation were higher in the presence of pulse pressure. PEG-catalase reduced flow-mediated dilation in static but not in pulse pressure, suggesting that in static conditions eNOS is responsible for O2 -/H2O2 production. Indeed, eNOS-derived O2 -/H2O2 production was measured during flow-mediated dilation in static pressure, while pulse pressure promoted eNOS-derived NO production. Differences in flow-mediated dilation between static and pulse pressure conditions were abolished after Nox2 inhibition. In conclusion, pulse pressure modulates cerebrovascular eNOS activity: at rest, pulse pressure inhibits eNOS, increasing myogenic tone. In the presence of flow, pulse pressure permits a shear stress-dependent eNOS-derived NO release, leading to higher flow-mediated dilation. pression pulsée dilatation induite par le flux tonus myogénique forces de cisaillement monoxde d'azote peroxyde d'hydrogène pulse pressure flow-mediated dilation myogenic tone shear stress nitric oxide hydrogen peroxide
120	Vestibular Evoked Myogenic Potentials: Preliminary Report Akin, Faith W., Murnane, Owen 01 January 2001 (has links) (PDF) Vestibular evoked myogenic potentials (VEMPs) are short-latency electromyograms evoked by high-level acoustic stimuli recorded from surface electrodes over the tonically contracted sternocleidomastoid (SCM) muscle. These responses are presumed to originate in the saccule. The purpose of this preliminary report is to provide an overview of our initial experience with the VEMP by describing the responses obtained in five subjects. Click-evoked VEMPs were present at short latencies in two normal-hearing subjects, one patient with profound congenital sensorineural hearing loss, and one patient with a severe sensorineural hearing loss due to Meniere's disease. Additionally, VEMPs were absent in a patient with profound sensorineural hearing loss following removal of a cerebellopontine angle tumor. The amplitude of the VEMP was influenced by the amount of background activity of the SCM muscle, stimulus level, and stimulus frequency. Tone-burst evoked responses showed an inverse relationship between stimulus frequency and response latency. VEMPs may prove to be a reliable technique in the clinical assessment of vestibular function. Vestibular function tests dizziness vestibular assessment sensorineural hearing loss saccule vestibular evoked myogenic potentials sternocleidomastoid muscle VEMP electromyography motor-evoked potentials vestibular nerve cyclophosphamide preliminary report Audiology and Speech-Language Pathology Speech and Hearing Science Speech Pathology and Audiology

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